JP2000506333A - Folded bowtie antenna - Google Patents

Abstract

(57) [Abstract] Small broadband antennas use conductive elements that are closely spaced and elongated to form a loop. The conductive loop has a pair of feeds located at the midpoint of the length of the loop, and the conductive loop is in the form of a bowtie, and receives over the VHF and UHF frequency bands. Can be.

Description

DETAILED DESCRIPTION OF THE INVENTION Folded bowtie antenna Industrial applications The present invention relates to an antenna for receiving a broadcast signal such as a television signal. Background of the Invention Conventional indoor TV antennas used for receiving in the VHF band use a pair of elastic elements, each element having a maximum length of 4 to 6 feet, forming a dipole. The two elements are usually mounted so that they can be spread apart to extend or contract the length of the dipole, and are commonly referred to as "rabbit ears". To receive the UHF band of a television indoors, it is customary to provide another antenna. A typical indoor UHF antenna is a loop having a diameter of about 71/2 inches. One problem associated with conventional indoor antenna systems is that two separate antennas for VHF and UHF broadcast signals do not provide efficient reception over the entire VHF and UHF frequency bands. An antenna is required. Second, such conventional indoor antennas do not have sufficient directivity to discriminate between normally received alternating path signals, and therefore often cause ghosting in television images. Third, "rabbit ear" antennas are unsightly in indoor environments because of their long elements and overall configuration. In order to efficiently receive across the VHF and UHF frequency bands, low cost, small, and robust antennas are required. Further, there is a need for an antenna having sufficient directivity to discriminate multipath signals. Further, there is a need for an antenna that can be used both indoors and outdoors. Summary of the Invention The present invention solves the above-described problems by providing an antenna comprising conductive elements that are closely spaced and elongated to form a loop. The conductive loop has a pair of feed points located at the midpoint of the length of the loop, and the conductive loop is in the form of a bow tie (bow tie) for receiving over the entire VHF and UHF frequency bands. can get. The present invention can be better understood with reference to the drawings. BRIEF DESCRIPTION OF THE FIGURES FIG. 1 shows an embodiment of a dual-purpose antenna for receiving satellite broadcast and local broadcast signals. FIG. 2 shows an embodiment of a dish reflector of the antenna shown in FIG. FIG. 3 shows a stand-alone folded bowtie antenna. FIG. 4 shows another embodiment of a dual purpose antenna system incorporating the features shown in FIGS. FIG. 5 schematically illustrates an embodiment of a voltage controlled antenna switch / amplifier. FIG. 6 schematically illustrates an embodiment of a tone controlled antenna switch / amplifier. FIG. 7 schematically illustrates an embodiment of a power conditioning circuit for generating control signals for the frequency converter and antenna switch / amplifier. FIG. 8 shows an antenna pattern associated with a switched folded bowtie antenna. FIG. 9-a shows another embodiment of a dual purpose antenna for receiving satellite and local broadcast signals. FIG. 9-b schematically shows the high-pass filter shown in FIG. 9-a. FIG. 10 shows another embodiment of a dual purpose antenna system including the features shown in FIG. 9-a. FIG. 11-a shows an embodiment of the reflector of the antenna system shown in FIG. FIG. 11-b illustrates features of the embodiment of the reflector shown in FIG. 11-a. In the above figures, identical or similar components are denoted by the same reference numerals. Detailed description of the invention FIG. 1 is a signal in a first frequency band that has been modified to also receive signals in another frequency band (eg, VHF and UHF signals from terrestrial broadcasters), such as microwave direct broadcast satellite (DBS). : Direct Broadcast Satellite (DTS) for receiving a signal. The dual purpose antenna shown in FIG. 1 includes a dish reflector 100, a frequency converter 11, and a frequency converter support arm 120. The frequency converter 11 is, for example, a conventional low noise block converter (LNB: Low Noise Block). The dish reflector 100 reflects and focuses the microwave transmitted from the direct broadcasting satellite (DBS). The frequency converter support arm 120 places the frequency converter 11 at the focal point of the reflected microwave signal. These dish reflectors can be manufactured using the so-called "injection molding" method. In this method, a conductive metal coating (eg, a nickel or copper coating) is applied to the surface of a dish-shaped member that is typically made of a lightweight insulating material (eg, plastic or glass fiber) to form a microwave reflector. ) Is painted. In accordance with the principles of the present invention, a reflector for receiving a DBS signal also includes an antenna element for receiving signals in the VHF / UHF band. In the case of dish-shaped reflectors produced by injection molding, the components for receiving signals in the VHF / UHF band are, as will be explained in detail below, by masking the conductive paint to form the dish-shaped members. Formed on the surface. As described below, it has been experimentally confirmed that incorporating a VHF / UHF element in a dish reflector does not reduce the relative function of the microwave reflector. In the step of forming the VHF / UHF antenna element on the surface of the dish-shaped member, the conductive paint is removed to produce a thin boundary (12 in FIG. 1). These boundaries separate the VHF / UHF antenna pattern from the rest of the conductive material. As predicted by theory and confirmed by experimentation, such thin lines, as long as they are kept at about one-tenth (or less) of the wavelength of the microwave broadcast signal, have the overall performance of the reflector. Has no adverse effect on For reference, see Johnson, Richard C .; And "Parabroidal Grid Reflector" in Jasik, Henry, "Reference Guide for Antennas" (Mc Graw Hill, 1987). For example, for the RCA Digital Satellite Service (DSS) available in the United States, the broadcast signal is 12. 2 GHz-12. It is transmitted between 7 GHz (K4 part of Ku band). Thus, an acceptable line width is about one tenth of an inch (2. 5 mm) or less. However, experiments have shown that line widths of 1/8 inch (3. 0 mm) or less, it has been proven that the microwave receiving performance does not decrease. Another aspect of the invention relates to the structure of the VHF / UHF antenna element. This structure is shown in FIG. 2-a and is hereinafter referred to as a "folded bowtie" antenna. It has been found that this folded bowtie antenna does not require adjustments to receive television broadcast signals across the VHF and UHF television frequency bands (54-870 MHz in the United States). This is because the folded bowtie antenna exhibits a wide frequency band and extends to the lower end (54 MHz) of the VHF low band television broadcast frequency. For example, John D. It is known from Kraus's antenna (see McGraw Hill, second edition, 1988, pp. 340-358) that a bow-tie-shaped biconical antenna has a relatively wider frequency bandwidth than a classic dipole antenna. FIG. 2-d shows experimental results, showing that the folded bowtie antenna features a significantly wider bandwidth than conventional designs, such as bowtie shaped biconical or folded dipole antennas. I have. As mentioned above, folded bowtie antennas can be easily formed on dish reflectors by using injection molding techniques. This is desirable for mass production of dual purpose antennas. Also, the cost of providing such a VHF / UHF antenna is significantly reduced compared to installing a separate antenna on the dish. The physical dimensions of an exemplary folded bowtie antenna have been determined experimentally and are shown in FIG. 2-a. In particular, for a dish antenna 100 having a width of 18 inches (46 cm), the length 220 of the folded bowtie antenna element is 18 inches (46 cm) and the width 210 is 9 inches (23 cm). The conductive paint also contributes to the broadband nature of the folded bowtie antenna on the dish. Any conductive paint is not completely conductive because of its resistivity. For example, a folded bowtie antenna made of nickel paint on a 18 inch (46 cm) diameter dish has a total resistance of about 17 ohms. Although this resistor may appear to degrade the performance of the folded bow-tie antenna as it weakens the received signal, it provides better antenna impedance matching over the entire VHF / UHF television frequency band. Thus, in fact, the overall performance of the folded bowtie antenna is enhanced. This resistor acts as a broadband load on the antenna. The improvement obtained by better impedance matching of the antenna outweighs the signal loss caused by the resistance. The compromise between signal loss and impedance matching is optimized by varying the resistivity of the conductive paint. Using a larger dish reflector and using an array of folded bowtie antenna elements further improves VHF / UHF reception. For example, a dish having a size of 18 inches or more could be used, and an array of folded bowtie antenna elements of the size described with respect to FIG. 2-a, two vertically stacked, as shown in FIG. 2-b. It can also be configured as By electrically integrating the signals received from the plurality of elements, an additional gain of 3 dB is obtained. In FIG. 2-a, the center of the element of the folded bowtie antenna 230 is split from the feed point, and each end (15 and 16) coincides with the outer edge of the reflector 100. The two elements are connected on one side 17 and separated on the other side at respective feed points (13 and 14). In addition to being formed on the surface of the dish in FIGS. 1 and 2-a, the structure of the folded bowtie antenna can be designed as a stand-alone antenna as shown in FIG. In the case of a stand-alone antenna, it is preferable to make the antenna smaller than in the embodiment described above, which is formed in a 18 inch (46 cm) dish. This is because small antennas can be easily placed in many different locations. FIG. 3 shows a relatively small folded bowtie antenna 30, which is a compromise between function and size. Experimental results have shown that the antenna 30 can achieve acceptable performance when 18 inches (46 cm) long and 4 inches (10 cm) wide. The elements of antenna 30 may be formed using various techniques, for example, by etching the structure of the antenna on a conventional circuit board, or by taping alumina or copper foil on a non-conductive sheet of substrate material (t). aping). In order to receive television or other broadcast signals, it is preferable to operate an antenna having a certain degree of directivity. This is because a directional antenna not only provides a larger signal, but also eliminates unwanted multipath signals and other disturbances. The folded bowtie antenna has an antenna pattern of "number 8". As shown in FIG. 2-c, in order to obtain the optimum VHF / UHF reception, the antenna. The receiving antenna should be arranged so that the lobe of the pattern is directed towards the transmitting antenna of the VHF / UHF television. One way to orient the antenna towards multiple transmitting antennas is to mechanically rotate the antenna. However, if the folded bowtie antenna is incorporated into a dish reflector as shown in FIGS. 1 and 2-a, it is not desirable to physically rotate the antenna. This is because the antenna receiving the DBS signal is typically fixed in a position pointing to a particular satellite. Also, physically rotating the antenna involves significant additional expense for the rotating device. Further, it will take about 10-20 seconds to rotate the antenna in the opposite direction (ie, 90 degrees). Each time a user changes channels, it may be necessary to adjust the antenna to find the optimal orientation of the antenna. Another feature of the present invention eliminates the need to rotate the antenna by providing a switchable folded bowtie antenna system. As shown in FIG. 4, the switchable folded bowtie antenna system has two folded bowtie antennas combined at right angles. The smaller folded bowtie antenna 430 is mounted below the frequency converter support arm 120. The three output signals (ie, the output of the smaller folded bowtie antenna 430, the output of the folded bowtie antenna 230 on the dish, and the output of the frequency converter 11) are separately provided to the switch / amplifier 40. For impedance matching, two 4: 1 balun transformers 50, 60 are provided on each of the two folded bowtie antennas. The terminals for the feed points 13, 14 are mounted behind the reflector and the balun transformer 50 is mounted below the dish. In response to a control signal generated by control circuit 60, switch / amplifier 40 selects an output signal from a folded bowtie antenna that is oriented toward the desired VHF / UHF transmit antenna. The control of the switching operation will be described in detail below. One coaxial cable may be used to transmit a plurality of different signals, for example, (1) a microwave signal to be down-converted; (2) a VHF / UHF broadcast signal; (3) a DC for the frequency converter 11 and a switch / amplifier. Power supply; and (4) a switching control signal for the switch / amplifier 40. Thus, the entire dual purpose antenna system is easily installed. An exemplary wiring connection is shown in FIG. FIG. 5 schematically shows an exemplary circuit 500 of the switch / amplifier 40. Switch / amplifier 500 includes amplifiers 520, 530; switching circuits D1, D2; switching control circuit 510; and diplex filter 560. As described below, the switching operation in the circuit of FIG. 5 is controlled by the DC level. FIG. 6 shows another exemplary circuit 600, which is responsive to an AC switching control signal (eg, a 22 kHz signal) as described below. Both embodiments of the switch / amplifier 40 select the folded bowtie antennas 230, 430 very quickly. In FIG. 5, two identical amplifiers 520, 530 include transistors Q3 and Q4. Each amplifier provides about 10 dB of gain. Conventional computer analysis and design techniques can be used to adjust gain, input and output impedance over the VHF / UHF television frequency band (54-870 MHz). Input filters U1 and U2 reject potential interference below 55 MHz. Switching is provided by PIN diodes D1 and D2 in response to power applied alternately to amplifiers 520 and 530. Switching voltage supply circuit 510 is configured such that when node V2 is 8 volts, node V1 is at zero volts. Thus, when node V2 is 8 volts, the collector of transistor Q3 (ie, the anode electrode of PIN diode D2) is at 5 volts due to R1, and the collector of transistor Q4 (the anode of PIN diode D1) is at 0 volts. . As a result, the PIN diode is forward biased and becomes conductive for RF signals. Thus, the amplified signal from input A is directed to output terminal 530. On the other hand, D1 is reverse biased, blocking the signal from input B. Further, since no voltage is supplied to transistor Q4, amplifier 530 does not provide a positive gain to the signal from input B, and in fact attenuates the signal from input B, and furthermore, inputs B from output terminal 530. Insulate. Also, when node V2 is at zero volts, node V1 is at 8 volts. Under such circumstances, the above operation is reversed and the signal from input B is amplified and directed to output terminal 530. As mentioned above, a DC power supply circuit in a television system (eg, a satellite tuner or a television receiver) can supply a DC power supply voltage to the switch / amplifier 40 via the center conductor of the coaxial cable. In the embodiment shown in FIGS. 5 and 6, such a DC power supply voltage (eg, 10-25 volts) is separated from the VHF / UHF broadcast signal by an inductance L5 and supplied to an input 515 of a regulator REG. You. The regulator REG supplies a regulated DC power supply voltage (eg, 8 volts) to the entire switch / amplifier circuit. As described in detail below, in response to antenna switching control information (i.e., changes in DC power supply voltage) transmitted from the television system, the control circuit 510 causes the PIN diodes D1 and D2 to apply different DC voltages to the PIN diodes D1 and D2, respectively. Supply bias voltage. The DC power supply voltage from this television system is supplied not only to the input of the regulator REG but also to the base electrode of the transistor Q2 via a voltage divider 511 including resistors R16 and R17. The adjusted DC power supply voltage is supplied to the emitter electrode of transistor Q2. If the television system has a relatively low DC power supply voltage (e.g., 14. 8 volts, the voltage divider 511 causes a lower bias voltage (e.g., 7. (4 volts or less) to the base electrode of transistor Q2, so that transistor Q2 turns on (ie, conducts). Thus, the adjusted power supply voltage appears at node V2 and forward biases PIN diode D2. On the other hand, transistor Q1 is off (ie, non-conductive) and node V1 is at zero volts. Therefore, no power is supplied to the amplifier 530 and the diode D2. Resistor R18 supplies the base current to transistor Q1, so that when Q2 turns off, Q1 turns on completely. A higher DC power supply voltage (e.g., 14. (8 volts or more), Q2 becomes non-conductive and Q1 becomes conductive. By adding the resistor R18, the control circuit 510 causes its threshold level (e.g., 14. 8 volts). The diplex filter 560 includes a low-pass filter 540 and a high-pass filter 550. The diplex filter 560 is designed to combine the VHF / UHF broadcast signal (55 to 803 MHz) and the converted microwave signal (950 to 1450 MHz), so that these signals are converted into one coaxial cable. Through the same center conductor. More specifically, a low pass filter 540 for a VHF / U HF broadcast signal (eg, having a cutoff frequency of 803 MHz) includes inductances L6, L7 and a capacitor C11. A high pass filter 550 for the converted microwave signal (eg, having a cut-off frequency of 950 MHz) includes an inductance L8 and capacitors C12 and C14. The inductances L9 and L10 and the capacitor C13 are provided to transmit the DC power supply voltage to the frequency converter 11. FIG. 6 shows a schematic diagram of another embodiment of the switch / amplifier 40. FIG. In this embodiment, an AC signal (e.g., 1. 5 volts PP) is used to control the switching function of switch / amplifier 40. Using a conventional oscillator, a tone signal is generated in the television system, and the tone signal is provided to or removed from the center conductor of the coaxial cable. The tone signal, if present, is provided to switching circuit 610 and rectified. The circuit 610 includes a tone rectifier circuit (C9, D4, D5, C10). The rectified tone signal causes transistors Q5 and Q2 to conduct. Thus, the regulated DC voltage (eg, 8 volts) is provided to node V2 'via transistor Q2. On the other hand, transistor Q1 is non-conductive and node V1 'is at zero volts. As a result, the transistor Q3 and the PIN diode D2 conduct, and the transistor Q4 and the PIN diode D1 are cut off. Therefore, the switch / amplifier circuit 600 selects the input A. FIG. 7 shows a DC power supply circuit 700 capable of adding a tone signal to the center conductor of a coaxial cable. This DC power supply circuit is used in a television system (for example, a satellite tuner or a television receiver) in order to supply different DC power supply voltages to the frequency converter 11 as shown in FIGS. Can be. The voltage generated by the circuit of FIG. 7 selects a circularly polarized wave (right-handed or left-handed circularly polarized wave) of the signal received by the converter 11. Also, the power supply circuit of FIG. 7 can provide DC power for the switch / amplifier 600 shown in FIG. Certain features of the circuit shown in FIG. 7 are known from US Pat. No. 5,563,500. Other features of the circuit shown in FIG. 7 will be described below. In FIG. 7, a control signal having two control states is coupled to one terminal of resistor 710. Depending on each control state, the circuit of FIG. 7 generates a different DC voltage at the output terminal 730 of FIG. For example, the state of the control signal of 0V generates 13V at the terminal 730, and the state of the control signal of 5V generates 17V at the terminal 730. Typically, output terminal 730 is coupled through a center conductor of a coaxial cable to a frequency converter or LNB as shown in FIGS. With each voltage, converter 11 receives a different signal polarization. For example, at 13 volts, converter 11 receives a right-handed polarized signal, and at 17 volts, converter 11 receives a left-handed polarized signal. Also in FIG. 7, the 22 kHz "tone" signal is coupled via capacitor C5 to the positive input of amplifier U1. When a 22 kHz tone signal is present, amplifier U1 and transistors Q2 and Q3 couple this 22kHz signal to the output signal at terminal 730. This circuit operates such that the signal at terminal 730 includes a 22 kHz signal (if present) and a selected DC level (eg, 13V or 17V). The presence or absence of a tone signal in the output signal is detected by the switching circuit of FIG. 6 and is used to switch the input signal of the folded bow-tie antenna. Accordingly, the circuit of FIG. 7 generates at terminal 730 an output signal combining the AC and DC control signals to independently control the polarization of the signal and the switching of the antenna. The DC voltage generated at the terminal 730 is used as a power supply for the switching amplifier of FIG. The particular state of the control signal and the presence or absence of a 22 kHz tone signal is determined by a controller within the television system, for example, a microcontroller (not shown). For example, the user actuates a particular key on the remote control to select a particular signal polarization or initiate switching of a folded bowtie antenna. Actuation of the key generates a remote control signal which is received by the microcontroller. The microcontroller processes the remote control signal and selects the appropriate function. For example, the microcontroller generates the proper state of the control signal provided to resistor R16 in FIG. 7, or controls a switch to couple (or decouple) the 22 kHz signal to capacitor C5. The switching operation of switch / amplifier 40 can be initiated in several different ways. For example, a user can use a remote control to manually select one of the folded bowtie antennas from channel to channel. Second, the selection can be made automatically by a microcomputer system; information is stored in the microcomputer regarding the channels associated with each antenna selection. If the user selects one of the antennas for a particular television broadcast channel, the same antenna will be automatically selected again when the same channel is selected later. Third, the microcomputer system may also automatically select the better VHF / UHF antenna by measuring an automatic gain control (AGC) signal indicating the level of the received VHF / UHF television signal. it can. This automatic selection is based on the so-called “auto. This program is preferably performed during the "auto program". If necessary, this selection can preferably be manually changed later by the user. The automatic antenna selection method described above provides a quick channel selection, "channel surfing". FIG. 8 shows the antenna pattern of a pair of switched orthogonal folded bowtie antennas. The dashed line shows the antenna 230 on the dish. The solid line represents the pattern of the antenna 430 mounted below the frequency conversion support arm 120 shown in Fig. 4. Compared to an omni-directional antenna (ie, an antenna covering 360 degrees), the potential Half of the multipath and jammers cut two folded bowtie antennas Fig. 9-a shows another embodiment of a dual purpose antenna, wherein the conductive screen is an insulative molded synthetic material. (Eg, plastic) to form a dish-shaped reflector 800. Since the screen cannot be easily made into a folded bowtie shape, a relatively simple shape should be used. As described above, 1/8 inch (3. 0 mm) is to split the screen into two parts with a minimum separation gap of less than or equal to 0 mm). The split conductive screen can also reflect microwave signals, and the split portions form dipole-type VHF and UHF antennas, respectively. These shapes can also be formed of a conductive paint as described above. In FIG. 9-a, the conductive screen is divided vertically and horizontally. The lower portion 930 of the screen is designed to operate as a dipole-type UHF antenna for optimal UHF reception, and the upper portion 940 combines with the lower portion 930 to form a VHF antenna. The lower part 930 is combined with the upper part within the range of the VHF television frequency to obtain the optimum VHF reception. Radio frequency (RF) filters 910, 920 are used as coupling means. Each filter is a simple parallel resonant trap similar to that used for amateur radio dipole antennas, or a high pass filter as shown in FIG. 9-b. Such a deformation can also be formed with a conductive paint. Some RF filters can be developed by masking conductive paint on the dish. FIG. 10 shows an exemplary antenna system for a conductive mesh reflector. The output of the dipole antenna in the dish is coupled to a balun transformer, which in turn is coupled to one of the inputs of a diplex filter (e.g., a Channel Master 4001 IFD). Other inputs of the diplex filter are also coupled to the output of the frequency converter to receive microwave broadcast signals from satellites. The combined output of the diplex filter is coupled to the television system via one coaxial cable (not two). Here, another diplex filter separates the VHF / UHF signal and the satellite signal from the combined signal, so that the conventional VHF / UHF television receiver and satellite tuner separate the two signals. Respectively can be received. In the embodiment of the VHF / UHF receiving system shown in FIG. 10, it has been found that good signal reception can be obtained when the broadcasting station is nearby (for example, within 20 miles). The VHF / UHF reception can be further improved by attaching radial rods to the screen as shown in FIG. 11-a. The radial rod makes the implantable dipole antenna function like a biconical antenna. The constant input impedance (Ri) of an "infinite" biconical antenna is given by: Ri = 120 ln cot Θhc / 2 (Ohm) where Θhc is as shown in FIG. 11-b. In the case of a finite biconical antenna in which the length of the antenna element is one wavelength or less of the reception frequency, the input impedance of the antenna becomes reactive. Accordingly, it is desirable to increase the effective length of the "cone" portion (ie, the screen). A rod or wire extending radially from behind the antenna is added. These rods are at an angle .theta.hc as shown in FIG. 11-b and control the input impedance of the antenna and particularly improve the reception of relatively low frequency signals within the VHF / UHF broadcast frequency band. Recent developments in NTSC reception technology, known as "programmable digital equalizers", are particularly advantageous for improving dual purpose antenna systems. This is because the equalizer can further reduce multipath and jamming problems for NTSC local broadcast signals. Although the present invention has been described with a certain degree of particularity, it is to be understood that the present disclosure is provided by way of example, and that changes in the details of construction may be made without departing from the spirit of the invention. For example, a dual-purpose antenna can be used to receive digital / analog audio or data signals as well as to receive digital / analog television signals.

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Claims (1)

[Claims] 1. Consists of closely spaced, elongated, conductive elements that form a loop ;   The conductive loop comprises a pair of feeds located at a midpoint of the length of the loop;   The loop is in the form of a bowtie and spans the entire VHF and UHF frequency bands Broadband antenna that can receive data. 2. The elongated conductive loop is a conductive material of the dish-shaped microwave reflector. Formed in part of the quality;   Due to the narrow non-conductive gap, the loop may be the rest of the conductive material. The reflector of claim 1, wherein the reflector maintains optimal microwave reflection. Broadband antenna. 3. A part of the remaining portion of the conductive material forms impedance conversion means. The broadband antenna according to claim 2, wherein 4. 3. A portion of the remaining portion of the conductive material forming a coupling means. The broadband antenna as described. 5. A first portion of the remaining portion of the conductive material is impedance conversion means. Form;   A second portion of said remaining portion of said conductive material forms a coupling means. Item 2. A broadband antenna according to item 2.